WO2012096049A1 - Base station device, terminal device, wireless communication system, and method - Google Patents

Abstract

The present invention enables proper communication even before acquiring a CQI report. A base station device (1b) which performs wireless communication with a terminal device (2) is provided with a report acquiring unit for acquiring a CQI report from a terminal device and a selection unit for selecting a transmission state. The transmission state includes a first transmission state where transmission is performed by using a first wireless resource subset (A) configured by including a wireless resource which does not receive interference from another base station device (1a) and a second transmission state where transmission is performed by using at least a second wireless resource subset (B) configured by including a wireless resource which is likely to receive interference from another base station device (1b). The report acquiring unit (14) acquires a CQI report for the second wireless resource subset from the terminal device (2). The selection unit (15) selects either one of the first transmission state or the second transmission state on the basis of the CQI report while selecting the first transmission state until the CQI report is acquired.

Description

Base station apparatus, terminal apparatus, radio communication system, and method

The present invention relates to a base station device, a terminal device, a wireless communication system, and a method.

Conventionally, in mobile communication systems, wireless communication services have been provided by base station apparatuses that form cells (macrocells) with a radius of several hundred meters to several tens of kilometers.
In recent years, with the introduction of LTE (Long Term Evolution), data communication traffic is expected to increase dramatically. Therefore, it has been studied to arrange a small base station apparatus that forms a cell (such as a pico cell) having a smaller cell radius than a macro cell within the macro cell area (see Non-Patent Document 1).
By moving a terminal device that performs a large amount of data communication from a macro cell to a pico cell and communicating from the pico cell, it is possible to cope with an increasing traffic.

Since the pico cell is arranged within the macro cell area, when the pico cell and the macro cell use the same communication frequency, there is a concern that a terminal device located near the cell edge of the pico cell may receive strong interference from the macro cell.
That is, near the center of the picocell cell (near the small base station device that forms the picocell), the radio wave from the small base station device that forms the picocell is stronger than the radio wave from the base station device that forms the macrocell. . Therefore, the communication quality of the pico cell terminal apparatus is relatively good.
However, the radio waves from the small base station apparatus become weaker when they are separated from the small base station apparatus forming the picocell. As a result, in the vicinity of the cell edge of the pico cell, it becomes easy to receive radio wave interference from the macro cell.

Therefore, it is conceivable to provide unused radio resources among radio resources that can be used by the macro cell. For example, in a frame transmitted by a macro cell, it may be possible to provide a section (blank subframe) in which a communication frequency is not used temporally. If the macro cell side is a blank subframe, the terminal device in the pico cell does not receive interference from the macro cell side. Therefore, the terminal device in the pico cell performs communication using the blank subframe, and suppresses communication quality deterioration due to interference from the macro cell by not performing communication as much as possible in a section where communication is performed in the macro cell. can do. Thereby, even if the terminal device is located in the vicinity of the cell edge of the pico cell, it is possible to suppress deterioration in communication quality.
Moreover, it is also conceivable to provide an unused frequency (blank carrier) among the frequencies (carriers) that can be used by the macro cell. The terminal device in the pico cell performs communication using the blank carrier and uses the carrier used for communication in the macro cell as much as possible, even if the terminal device is located near the cell edge of the pico cell, Reduces communication quality

However, in the vicinity of the cell center of the pico cell (near the small base station device forming the pico cell), there is originally little interference from the macro cell, so that the terminal device performs communication in the section or frequency used for communication in the macro cell. However, a decrease in communication quality is not a problem. Therefore, from the viewpoint of communication efficiency, it is desirable to actively use communication even for radio resources used for communication in a macro cell for a terminal device located near the cell center of a pico cell.

According to the above viewpoint, the radio resource preferable for the terminal apparatus to use for communication depends on the position of the terminal apparatus in the cell (distance from the base station apparatus).
Here, in order for the base station apparatus to recognize the position of the terminal apparatus in the cell (distance from the base station apparatus), the terminal apparatus measures the communication quality and transmits the result to the base station apparatus. Yes. However, in order to recognize the position of the terminal device in the cell (distance from the base station device) in this way, it is necessary to perform communication between the base station device and the terminal device.

Therefore, before the terminal device establishes a connection with the base station device, the base station device cannot recognize the position of the terminal device in advance. Then, when the recognition of the position of the terminal device is delayed, there arises a problem that it is delayed that communication between the base station device and the terminal device can be performed using appropriate radio resources.

Therefore, the present invention has been made in connection with the solution of the above problems.

(1) The present invention is a base station device that performs wireless communication with a terminal device, and a report acquisition unit that acquires a report regarding a measurement result of communication quality from the terminal device, and a selection unit that selects a transmission state The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that are not subject to interference from other base station apparatuses. And at least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from another base station apparatus. And the report acquisition unit sends a report on the measurement result of the communication quality of one or more radio resource subsets including the second radio resource subset to the terminal device. When the report is acquired, the selection unit selects one of the first transmission state and the second transmission state as a transmission state to the terminal device based on the report, and Until the report is acquired, the first transmission state is selected as the transmission state to the terminal device.

According to the present invention, until a report is acquired, transmission is performed using the first radio resource subset configured to include one or more radio resources that do not receive interference from other base station apparatuses. The first transmission state is selected. Therefore, even if report acquisition is delayed, communication in the first transmission state that is less susceptible to interference is guaranteed until the report is acquired.

(2) A notification unit for notifying subset information indicating one or more radio resource subsets including the second radio resource subset is further provided, and the notification unit can notify the terminal device of the subset information. It is preferable to notify the subset information to another base station apparatus. In this case, subset information can be notified to the terminal device via the other base station device.

(3) A notification unit for notifying subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset is further included, and the notification unit is used for the terminal device to perform handover to the own base station device. It is preferable to notify the subset information to the source base station apparatus in the handover process during the handover process. In this case, it is possible to notify subset information to the terminal device via the source base station device during the handover process.

(4) It is preferable that the notification unit notifies the source base station apparatus of the subset information by including the subset information in a message transmitted to the source base station apparatus for handover processing. In this case, subset information can be notified using a message for handover processing.

(5) It is preferable that the message transmitted to the source base station apparatus for the handover process is a response to the handover request transmitted from the source base station apparatus.

(6) It is preferable that the base station device further includes a notification unit that notifies the terminal device of subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset. In this case, the base station apparatus can notify the terminal apparatus of the second radio resource subset whose communication quality is to be measured.

(7) It is preferable that the notification unit transmits the subset information as broadcast information.

(8) It is preferable that the notification unit notifies the terminal device of the subset information during a connection establishment process for establishing a connection between the terminal device and the base station device. In this case, the terminal device can acquire the subset information relatively early.

(9) The notification unit includes the subset information in a message transmitted from the base station apparatus to the terminal apparatus for establishing a connection between the terminal apparatus and the base station apparatus, thereby It is preferable to notify the terminal device. In this case, the terminal device can acquire the subset information relatively early.

(10) In the second transmission state, it is preferable that transmission is performed using the first radio resource subset and the second radio resource subset.

(11) The radio resource is preferably a time resource or a frequency resource.

(12) The radio resource is preferably a subframe or a carrier.

(13) The present invention from another viewpoint is a terminal device that performs wireless communication with a base station device, and includes one or a plurality of radio resources that may be interfered with by another base station device. A measurement unit that measures communication quality of a radio resource subset configured by: a transmission unit that transmits a report on a measurement result by the measurement unit to the base station apparatus; and a radio resource subset whose communication quality is to be measured by the measurement unit And a subset information acquisition unit that acquires subset information from the base station apparatus.

(14) It is preferable that the acquisition unit acquires the subset information from the other base station device.

(15) The acquisition unit preferably acquires the subset information from a source base station apparatus in a handover process.

(16) The subset information is included in broadcast information transmitted from the base station apparatus, and the subset information acquisition unit acquires the subset information by receiving the broadcast information from the base station apparatus. It is preferable to do this.

(17) The measurement unit measures communication quality of a radio resource subset indicated by the subset information included in the broadcast information received before connection establishment processing for establishing a connection between the terminal device and the base station device. The transmitting unit preferably transmits the report during the connection establishment process.

(18) The subset information is included in a message transmitted from the base station apparatus to the terminal apparatus for establishing a connection between the terminal apparatus and the base station apparatus, and the subset information acquisition unit includes: It is preferable to acquire the subset information by receiving the message from the base station apparatus.

(19) From another viewpoint, the present invention is a wireless communication system including a base station device and a terminal device that performs wireless communication with the base station device, wherein the base station device A report acquisition unit that acquires a report on the measurement result of the terminal device from the terminal device, and a selection unit that selects a transmission state, and the transmission state includes one or more radios that are not subject to interference from other base station devices A first transmission state in which transmission is performed using a first radio resource subset configured to include resources, and one or more radio resources that may receive interference from other base station apparatuses At least a second transmission state in which transmission is performed using at least the second radio resource subset to be transmitted, and the report acquisition unit includes one or more of the second radio resource subsets. A report on the measurement result of the communication quality of the radio resource subset of the first radio resource subset from the terminal device, and when the report is acquired, the selection unit, based on the report, as a transmission state to the terminal device A wireless device that selects one of a first transmission state and a second transmission state and selects the first transmission state as a transmission state to the terminal device until the report is acquired. It is a communication system.

(20) The base station device further includes a notification unit that notifies subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset, and the notification unit is configured to notify the terminal device. It is preferable that the subset information is notified to another base station apparatus that can notify the subset information, and the other base station apparatus notifies the terminal apparatus of the subset information.

(21) The present invention from another viewpoint is a method in which a base station apparatus selects a transmission state, and the transmission state includes one or a plurality of radio resources that are not subject to interference from other base station apparatuses. A first transmission state in which transmission is performed using the first radio resource subset configured by the first radio resource, and a first transmission state configured to include one or a plurality of radio resources that may receive interference from other base station apparatuses. At least a second transmission state in which transmission is performed using at least two radio resource subsets, and the base station apparatus measures the communication quality of one or more radio resource subsets including the second radio resource subset Until the report regarding the terminal device is acquired, the first transmission state is selected as the transmission state to the terminal device, and when the report is acquired, Based on the port, a method characterized by selecting one of the first transmission mode and a second transmission state as the transmission state to the terminal device.

(22) The present invention from another viewpoint is a method for transmitting information from a base station apparatus to a terminal apparatus, wherein the information is one or more radio resources to be measured by the terminal apparatus for communication quality The base station apparatus notifies the base station apparatus of the subset information that can be notified of the subset information to the terminal apparatus. Then, the another base station apparatus transmits the subset information to the terminal apparatus.

(23) The present invention is a base station device that performs wireless communication with a terminal device, and a report acquisition unit that acquires a report regarding a measurement result of communication quality from the terminal device, and a selection unit that selects a transmission state The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that are not subject to interference from other base station apparatuses. And at least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from another base station apparatus. And the report acquisition unit reports a report on a measurement result of communication quality of one or a plurality of radio resource subsets including the second radio resource subset to the terminal device. And the selection unit selects one of the first transmission state and the second transmission state as the transmission state to the terminal device based on the report transmitted from the terminal device, and the report The report acquired by the acquisition unit indicates communication quality of one or a plurality of the radio resource subsets including the second radio resource subset to the terminal device before connection between the terminal device and the base station device is established. The base station apparatus is related to a measurement result obtained by measurement.

According to the present invention, since the communication quality is measured before the connection is established, the base station apparatus can obtain a report related to the measurement result of the communication quality relatively early. . Therefore, the selection of the first transmission state or the second transmission state can be performed relatively early.

(24) It is preferable to further include a notification unit that notifies the terminal device of subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset. In this case, the base station apparatus can notify the terminal apparatus of a radio resource subset whose communication quality is to be measured.

(25) It is preferable that the notification unit transmits the subset information as broadcast information (Broadcast Information). In this case, the terminal device can acquire the subset information even if the connection between the terminal device and the base station device is not established.

(26) The notification unit may notify the subset information to the terminal device during a location registration process for registering an area where the terminal device is located. In this case, the terminal device can acquire the subset information when returning to the idle mode after the location registration process.

(27) It is preferable that the report acquisition unit acquires the report from the terminal device during a connection establishment process for establishing a connection between the terminal device and the base station apparatus or immediately after the connection establishment process. In this case, the base station apparatus can acquire a report relatively early.

(28) The report is included in a message transmitted from the terminal device to the base station device to establish a connection between the terminal device and the base station device, and the report acquisition unit includes the message It is preferable to acquire the report by receiving the message from the terminal device. In this case, the base station apparatus can acquire the report at an early stage during connection establishment processing.

(29) The report acquisition unit is transmitted from the terminal device to the base station device to establish a connection between the terminal device and the base station device during the connection establishment process or immediately after the connection establishment process. It is preferable to acquire the report from the terminal device separately from the message. In this case, the base station apparatus can acquire the report at a relatively early stage, such as during connection establishment processing or immediately after connection establishment processing.
(30) The selection unit can perform selection based on communication quality of the second radio resource subset or based on communication quality of the first radio resource subset and the second radio resource subset.
(31) It is preferable that the selection unit selects the first transmission state as a transmission state to the terminal device until the report is acquired. In this case, interference can be avoided even before the report is acquired.

(32) From another viewpoint, the present invention is a terminal device that performs wireless communication with a base station device, and includes one or a plurality of radio resources that may be interfered with by another base station device. A measurement unit that measures communication quality of a radio resource subset configured by: a transmission unit that transmits a report on a measurement result by the measurement unit to the base station apparatus, and the measurement unit includes: The terminal device is characterized in that the communication quality is measured before the connection between the terminal device and the base station device is established.

According to the present invention, since the communication quality is measured before the connection is established, the base station apparatus can obtain a report related to the measurement result of the communication quality relatively early.

(33) A function of acquiring the radio resource subset from the base station device is provided as a function of an RRC layer, the measurement unit is provided as a function of a PHY layer, and the measurement unit of the PHY layer is configured of the RRC layer. Alternatively, it is preferable to measure the communication quality of the radio resource subset based on timing controlled in a layer between the RRC layer and the PHY layer. In this case, appropriate function distribution between the RRC layer and the MAC layer is realized.

(34) It is preferable to further include a control unit that controls timing at which the measurement unit measures the communication quality of the radio resource subset. In this case, measurement timing control is possible.

(35) It is preferable that the control unit periodically gives an instruction to measure the communication quality of the radio resource subset to the measurement unit. In this case, the measurement is performed periodically.

(36) When an event that triggers the start of a connection establishment process for establishing a connection between the terminal device and the base station device occurs, the control unit determines the communication quality of the radio resource subset to the measurement unit. An instruction for measurement may be given. In this case, measurement is performed at the event trigger.

(37) It is preferable that a subset information acquisition unit that acquires subset information indicating the radio resource subset from the base station apparatus is further provided. In this case, information indicating the radio resource subset to be measured can be acquired from the base station apparatus.

(38) It is preferable that the subset information acquisition unit acquires the subset information transmitted as broadcast information from the base station apparatus from the base station apparatus. In this case, the terminal device can acquire the subset information even if the connection between the terminal device and the base station device is not established.

(39) It is preferable that the subset information acquisition unit acquires the subset information from the base station device during a location registration process for registering an area where the terminal device is located. When the terminal device returns to the idle mode after the location registration process, it can acquire the subset information.

(40) It is preferable that the transmission unit transmits the report to the base station apparatus during a connection establishment process for establishing a connection between the terminal apparatus and the base station apparatus or immediately after the connection establishment process. In this case, the base station apparatus can acquire a report relatively early.

(41) The transmission unit includes the report in a message transmitted from the terminal device to the base station device to establish a connection between the terminal device and the base station device, thereby allowing the report to be transmitted. It is preferable to transmit to the base station apparatus. In this case, the base station apparatus can acquire the report at an early stage during connection establishment processing.

(42) The transmitter is transmitted from the terminal device to the base station device for establishing a connection between the terminal device and the base station device during the connection establishment process or immediately after the connection establishment process. Apart from the message, it is preferable to transmit the report to the base station apparatus. In this case, the base station apparatus can acquire the report at a relatively early stage, such as during the connection establishment process or immediately after the connection establishment process.

(43) The present invention viewed from another viewpoint is a wireless communication system including a base station device and a terminal device that performs wireless communication with the base station device, wherein the base station device A report acquisition unit that acquires a report on the measurement result of the terminal device from the terminal device, and a selection unit that selects a transmission state, and the transmission state includes one or more radios that are not subject to interference from other base station devices A first transmission state in which transmission is performed using a first radio resource subset configured to include resources, and one or more radio resources that may receive interference from other base station apparatuses At least a second transmission state in which transmission is performed using at least the second radio resource subset to be transmitted, and the report acquisition unit includes one or more of the second radio resource subsets. A report on the measurement result of the communication quality of the radio resource subset is obtained from the terminal device, and the selection unit is configured to transmit the first transmission state to the terminal device based on the report transmitted from the terminal device. Either one of a transmission state and the second transmission state is selected, and the terminal device measures a communication quality of one or a plurality of the radio resource subsets including the second radio resource subset, and the measurement A transmission unit that transmits a report on a measurement result by the unit to the base station device, and the measurement unit performs the measurement of the communication quality before the connection between the terminal device and the base station device is established. This is a wireless communication system.

(44) The present invention viewed from another viewpoint includes a measurement step in which the terminal device measures downlink communication quality, and a transmission step in which the terminal device transmits a report on the measurement result of the communication quality to the base station device, A first radio resource subset configured to include one or a plurality of radio resources that are not subject to interference from other base station apparatuses. Using at least a first transmission state in which transmission is performed using a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from another base station apparatus At least a second transmission state in which transmission is performed, and in the measurement step, communication quality of the second radio resource subset is measured, and the selection step Then, based on the report transmitted from the terminal device, one of the first transmission state and the second transmission state is selected as a transmission state to the terminal device, and the measurement step is performed with the terminal device. The method is performed before the connection with the base station apparatus is established.

(45) The present invention from another viewpoint is a transmission method from a base station apparatus to a terminal apparatus, and the base station apparatus includes one or a plurality of radio resources that the terminal apparatus should measure communication quality. In this method, subset information indicating a configured radio resource subset is included in broadcast information and transmitted.

(46) Another aspect of the present invention is a transmission method from a base station apparatus to a terminal apparatus, wherein the base station apparatus includes one or a plurality of radio resources that the terminal apparatus should measure communication quality. This is a method characterized in that subset information indicating a configured radio resource subset is included in a message in radio connection control and transmitted.

(47) Another aspect of the present invention is a transmission method from a terminal apparatus to a base station apparatus, wherein a report of a communication quality measurement result is included in a message in wireless connection control and transmitted. Is the method.

It is a block diagram of a communication system. It is a block diagram of the network between base stations. It is a structural diagram of a DL frame and a UL frame. It is a structural diagram of a DL frame. It is a figure which shows the inter-cell interference of macro BS and pico BS. It is a figure which shows the example of the pattern of a subset combination. (A) is a block diagram of a base station apparatus (pico BS), (b) is a block diagram of a terminal device. It is a sequence which shows the process sequence for transmission state selection. It is explanatory drawing of the acquisition method of ABS information. This is a sequence for selecting a transmission state. It is a specific example of subset information. It is a specific example of RadioResourceConfigDedicated. It is a 2nd example of the sequence for transmission state selection. It is a figure which shows the hand-over from a macro cell to a pico cell. It is a sequence for transmission state selection at the time of handover. It is a sequence for transmission state selection at the time of handover. (A) is a block diagram of a base station apparatus (pico BS), (b) is a block diagram of a terminal device. It is a state transition diagram of a terminal device. It is a figure which shows the notification method of the subset information using alerting | reporting information. It is a state transition diagram of a terminal device. It is a sequence of a location registration process. It is a specific example of SIB2. It is the sequence at the time of CQI measurement of a terminal device. It is a sequence of a CQI measurement instruction. It is a sequence of CQI report transmission. It is a specific example of a CQI report. It is a specific example of an RRCConnectionRequest message. It is a specific example of an RRCConnectionSetupComplete message. It is a specific example of an RRCConnectionReconfigurationComplete message. It is a sequence of CQI report transmission. It is a flowchart of the pre-process of a connection establishment process. This is a sequence for selecting a transmission state.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
[1. Configuration of communication system]
FIG. 1 is a schematic diagram illustrating a configuration of a wireless communication system. This communication system is a cell system including a plurality of base station apparatuses (BSs) 1. The radio communication system of this embodiment is a system to which LTE is applied, for example, and communication based on LTE is performed between each base station apparatus 1 and a terminal apparatus (UE; User Equipment) 2. However, the communication method is not limited to LTE.

The plurality of base station apparatuses 1 constituting the communication system include, for example, a plurality of macro base station apparatuses (Macro Base Station) 1a forming a communication area (macro cell) MC having a size of several kilometers, and smaller than the macro cell. Small base station apparatuses 1b and 1c forming a cell can be included. As a small base station apparatus, there are, for example, a pico base station apparatus 1b that forms a picocell PC and a femto base station apparatus 1c that forms a femtocell FC.
Hereinafter, the macro base station apparatus is referred to as a macro BS, the pico base station apparatus is referred to as a pico BS, and the femto base station apparatus is referred to as a femto BS.

One or more pico BSs 1b are installed in the macro cell. Similar to the macro BS 1a, the pico BS 1b is mainly installed by a communication carrier. By connecting the terminal device (mobile terminal) 2 in the macro cell MC to the pico BS 1b instead of the macro BS 1a, the communication load on the macro BS 1a can be reduced, and the throughput of the entire system can be improved.

One or more femto BSs 1c are also installed in the macro cell. The femto BS 1c is installed mainly by individuals or companies who are customers (users) of the communication system. By installing the femto BS 1c, it is possible to improve the communication environment at the place where the femto base station apparatus is installed.

Both the femtocell FC and the picocell PC have a communication area narrower than that of the macrocell MC. However, as the names “femto” and “pico” indicate, the femtocell FC is generally narrower than the picocell PC.
In LTE, the macro BS and the pico BS are called “eNB”, and the femto BS is called “HeNB”.

FIG. 2 shows an inter-base-station network (wired network) connecting the base station apparatuses of the macro BS 1a, the pico BS 1b, and the femto BS 1c. The macro BS 1a and the pico BS 1b, which are eNBs, are connected to an MME (Mobility Management Entity) via a line 6 using a communication interface called an S1 interface. The MME 3 is a management device that manages the position and the like of the terminal device 2, and is a node that performs processing for movement management of each terminal device 2.
Further, the eNBs are connected to each other via a line 7 using a communication interface called an X2 interface, and communication for information exchange can be directly performed between the eNBs. However, in the current standard, the femto BS 1c cannot have an X2 interface.
In addition, the connection by X2 interface is not restricted to the connection shown in FIG. 2, It can provide between arbitrary eNBs.

A femto BS 1 c that is a HeNB is connected to the MME 3 via a HeNB gateway (GW) 5. The MME 3 and the gateway 5 and the gateway 5 and the femto BS 1c are also connected by lines 6 using communication interfaces called S1 interfaces, respectively.
Note that the femto BS 1c may be connected to the MME 3 through the S1 interface without going through the HeNB gateway (GW) 5.

The network based on the S1 interface and the X2 interface constitutes an inter-base station network that connects the base station apparatuses 1a, 1b, and 1c with wires. In this inter-base station network, a server (not shown) for managing communication is installed.
In addition, between each base station apparatus 1a, 1b, 1c is ensuring the synchronization between base stations using the network between base stations.

[2. LTE frame structure]
In the FDD scheme that can be adopted in LTE that the communication system according to the present embodiment complies with, an uplink signal (a transmission signal from the terminal device to the base station device) and a downlink signal (a transmission signal from the base station device to the terminal device) By assigning different use frequencies to each other, uplink communication and downlink communication are simultaneously performed.

FIG. 3 is a diagram showing the structure of uplink and downlink radio frames in LTE. The radio frame (DL frame) and the uplink radio frame (UL frame), which are downlink basic frames in LTE, each have a time length of 10 milliseconds, and there are 10 frames from # 0 to # 9. Subframes (communication unit areas having a fixed time length). These DL frames and UL frames are arranged in the time axis direction with their timings aligned.

FIG. 4 is a diagram illustrating a detailed structure of a DL frame (a transmission frame of the base station apparatus). In the figure, the vertical axis direction represents frequency, and the horizontal axis direction represents time.
Each subframe constituting the DL frame is composed of two slots. One slot is composed of seven (# 0 to # 6) OFDM symbols (in the case of Normal Cyclic Prefix).
Also, in the figure, a resource block (RB: Resource Block) that is a basic unit area in data transmission is defined by 12 subcarriers in the frequency axis direction and 7 OFDM symbols (1 slot) in the time axis direction.
Further, the bandwidth in the frequency direction of the DL frame is specified as a plurality of set values with a maximum of 20 MHz.

As shown in FIG. 4, at the head of each subframe, a transmission area is allocated for the base station apparatus 1 to allocate a control channel necessary for downlink communication to the terminal apparatus 2. This transmission area is allocated with symbols # 0 to # 2 (three symbols at the maximum) of slots located on the head side in each subframe. PDCCH, PCFICH, PHICH, etc. are allocated to this transmission area.

Of the ten subframes constituting the DL frame, each of the first (# 0) and sixth (# 5) subframes is a control signal for identifying a base station apparatus or a cell. A synchronization signal and a second synchronization signal (P-SCH: Primary Synchronization Channel, S-SCH: Secondary Synchronization Channel) are assigned to the synchronization signal and the second synchronization signal (P-SCH: Primary Synchronization Channel, S-SCH: Secondary Synchronization Channel).

In the DL frame, a broadcast channel (PBCH: Physical Broadcast Channel) for notifying the terminal device of the system bandwidth and the like by broadcast transmission is assigned to the first subframe # 0. The PBCH is arranged with four symbol widths at the positions of symbols # 0 to # 3 in the slot on the rear side in the first subframe # 0 in the time axis direction, and the center of the bandwidth of the DL frame in the frequency axis direction Are allocated for 6 resource block widths (72 subcarriers). This broadcast channel is configured to be updated every 40 milliseconds by transmitting the same information over four frames.
A master information block (MIB: Master Information Block) including a communication bandwidth, a radio frame number, and the like is stored in the PBCH.

Other resource blocks to which the above-described channels are not allocated are used as DL shared channels (PDSCH) for storing user data and the like. This PDSCH is an area shared by a plurality of terminal devices.
The allocation of user data stored in the PDSCH is notified to the terminal device by resource allocation information regarding downlink radio resource allocation stored in the PDCCH allocated at the head of each subframe. This resource allocation information is information indicating radio resource allocation of each PDSCH, and the terminal apparatus can recognize that data for itself is stored in the subframe by this resource allocation information.
The P-SCH, S-SCH, PBCH, PDCCH and other control channels contain various control signals necessary for the terminal device 2 to receive data signals transmitted on the PDSCH. When the channel receives radio wave interference, it interferes with reception of the data signal transmitted by the PDSCH.

In addition, in addition to user data, PDSCH stores control signals common to each terminal device, individual control signals for each terminal device, and the like. Examples of the control signal stored in the PDSCH include broadcast information such as a system information block (SIB: System Information Block).

There are SIB1 to SIB9 as system information blocks. The timing at which SIB1 is transmitted is specified by MIB. Scheduling information of SIB2 to SIB9 is included in SIB1. Therefore, the notification information such as SIB can be read by the terminal device even if the terminal device 2 has not established a connection with the base station device 1. Note that the number of SIBs is not particularly limited.

[3. Inter-Cell Interference]
As shown in FIG. 1, since the radio wave (interference wave) from the macro BS 1a is likely to reach the terminal device 2a located near the cell edge of the pico cell PC, the intensity of the radio wave (desired wave) from the pico BS 1b is weak. There is a possibility of receiving interference from the macro BS 1a.
Note that the relatively strong radio wave from the pico BS 1b reaches the terminal device 2b located near the cell center of the pico cell PC (near the pico BS 1b), so that the influence of interference from the macro BS 1a is small.

In order to reduce the interference from the macro BS 1a to the terminal device 2 located in the vicinity of the cell edge of the pico cell PC, it is only necessary to secure an unused radio resource among radio resources that can be used by the macro BS 1a. For example, as shown in FIG. 5A, a section (time as a radio resource) where the macro BS 1a does not use the communication frequency may be provided in the transmission frame of the macro BS 1a. If the pico BS 1b performs transmission to the terminal device 2a connected to the pico BS 1b in a section where the macro BS 1a is not used, interference from the macro BS 1a is eliminated.
The radio resource that is not used may be a frequency. For example, among the frequencies (carriers) that can be used by the macro BS 1a, a frequency (blank carrier) that is not used may be secured. If the pico BS 1b performs transmission to the terminal device 2a connected to the pico BS 1b at a frequency (blank carrier) not used by the macro BS 1a, the interference from the macro BS 1a is eliminated.
In the following description, a subframe will be described as an example of a radio resource, but the following description is also applied to a case where the radio resource is a frequency (carrier).

FIG. 5B shows an example in which an ABS (Almost Blank Subframe) is provided in the transmission frame of the macro BS 1a as a specific example in which a section in which the macro BS 1a does not use the communication frequency is provided. The ABS is a blank subframe that includes a reference signal (CRS; Cell-speciffic Reference Signal) and / or other minimum required control signals but does not include a data signal (PDSCH).
As shown in FIG.5 (c), the sub-frame of pico BS1b of the timing corresponding to ABS of macro BS1a becomes a subframe which does not receive the interference from macro BS1a. Therefore, the pico BS 1b can avoid interference from the macro BS 1a to the terminal device 2a connected to the pico BS 1b by performing transmission in a subframe at a timing corresponding to the ABS of the macro BS 1a.

Therefore, the pico BS 1b transmits interference to the terminal apparatus 2a located near the cell edge of the pico cell in a subframe subset including many subframes having timings corresponding to the ABS of the macro BS 1a, thereby preventing interference from the macro BS 1a. The impact can be reduced.

FIG. 6 shows an example of a pattern in which one wireless transmission frame is composed of two subsets A and B. The subset is a subframe subset whose elements are subframes. Each subframe (# 0 to # 9) constituting one radio transmission frame belongs to one (or both) of two subsets A and B.

In pattern 1, subframes # 2, # 5, and # 8 belong to the first subframe subset A, and # 0, # 1, # 3, # 4, # 6, # 7, and # 9 are second subframes. Belongs to a subset. When the macro cell side ABS is provided at # 2, # 5, and # 8, pico BS 1b performs transmission using subframes # 2, # 5, and # 8 belonging to first subframe subset A Thereby, even if the terminal device 2a is located in the vicinity of the cell edge, interference from the macro cell can be avoided.
On the other hand, when the terminal device 2b connected to the pico BS 1b is located near the center of the pico cell (near the pico BS 1b), subframes # 0, # 1, # 3, # 3 belonging to the second subframe subset B Even if transmission is performed using 4, # 6, # 7, # 9 or the entire frame (all of # 0 to # 9), there is little interference from the macro cell side.

Thus, when the ABS pattern on the macro cell side is as shown in FIG. 6, the first subframe subset A is suitable for transmission to the terminal apparatus 2a near the cell edge, and the second subframe subset is used. B or the entire frame is suitable for transmission to the terminal device 2b near the center of the pico cell.
Therefore, the pico BS 1b can reduce interference by determining the subframe used for transmission to the terminal 2b according to the position of the terminal device 2b (near the cell edge or near the cell center).

In FIG. 6, the macro cell subframe numbers (# 0 to # 9) and the pico cell subframe numbers (# 0 to # 9) are temporally aligned, but the frame numbers may not be aligned. In FIG. 6, the patterns are defined by only 10 subframes included in one frame for subsets A and B, but are defined by a plurality of frames (for example, 40 subframes for 4 frames). May be.

The example of the two subsets A and B constituting one radio transmission frame is not limited to the pattern 1, and a plurality of patterns such as the patterns 2 to 4 can be provided as shown in FIG.
By providing a plurality of patterns, it is possible to appropriately select an appropriate pattern according to the ABS pattern (ABS position in the frame) on the neighboring macro cell side.

As shown in patterns 1 to 4 in FIG. 6, the number of subframes constituting each subset A and B is not particularly limited. Further, as in pattern 4, there may be subframes belonging to both of two subsets A and B (see subframe # 8 of pattern 4).
Furthermore, the subset is not limited to two, and may be three or more.

In the case of the ABS pattern of the macro cell in FIG. 6, in the patterns 1 to 4 in FIG. 6, the subset A includes a subframe corresponding to the ABS (# 2, # 5, # 8) of the macro cell. , More than subset B. That is, the subset A is a first subframe subset that includes one or a plurality of subsets that do not receive interference from the macro BS 1a.
Further, in the case of the ABS pattern of the macro cell of FIG. 6, in the patterns 1 to 4 of FIG. 6, the subset B may receive interference from the macro BS 1a (# 0, # 1, # 3, # 4, # 4 6, # 7, # 9) is a second subframe subset configured to include one or more of them.

As a blank subframe, in addition to ABS, a subframe (MBSFN) for MBMS (Multimedia Broadcast Multicast Service) may be used. MBMS is a broadcast service such as a TV broadcast service, and the same information is transmitted from a plurality of base station apparatuses using the same resource at the same timing.
Since MBMS is a broadcast service, in the MBSFN subframe used for MBMS, in addition to the information related to MBMS, the necessary minimum control information such as the fact that the subframe is an MBSFN subframe is sent to the control channel (the head of the subframe). Control information directed to a specific terminal device is not transmitted.

In this embodiment, since the MBSFN is blank, a null signal is set as a data signal in the MBSFN transmitted by the macro BS 1a. Since MBSFN that transmits a null signal does not need to include a reference signal, it is closer to a more complete blank subframe than ABS.
As described above, the blank subframe (the communication frequency non-use section) does not need to be a signal that does not exist at all, and it is sufficient if a signal blank substantially exists.
In addition, even if the blank subframe is actually used, the power of the signal may be suppressed to be small, and it may be considered that the blank subframe is not substantially used when sufficiently separated from the base station apparatus. .

[4. Configuration of base station apparatus and terminal apparatus]
FIG. 7A shows the configuration of the pico BS 1 b, and FIG. 7B shows the configuration of the terminal device 2. Note that the configuration of FIG. 7A may be included in the femto BS 1c.

The pico BS 1b includes an ABS information acquisition unit 11, a pattern selection unit 12, a subset information notification unit 13, a CQI report acquisition unit 14, and a selection unit 15.
The ABS information acquisition unit 11 receives information (ABS information) indicating the position of an ABS (blank subframe) in a transmission frame transmitted from the macro BS 1a (other base station apparatus) from the macro BS 1a (other base station apparatus). It is for acquisition.

The pattern selection unit 12 selects a pattern indicating a combination of the two subsets A and B. The subset information notification unit 13 notifies the terminal device 2 of information (subset information) of the subframe subsets A and B in the pattern selected by the pattern selection unit 12.
The subset information is information that allows the terminal device 2 to specify at least the subframes constituting the second subframe subset B. The subset information may include information that allows the terminal device 2 to specify the subframes constituting the first subframe subset A.

The CQI report acquisition unit 14 acquires a CQI (Channel Quality Indicator) report from the terminal apparatus (UE) 2.
The CQI report relates to a measurement result of communication quality measured by the terminal apparatus 2 for the subset constituting the second subframe subset B. Further, the CQI report may include information related to the measurement result of the communication quality measured for the subset constituting the first subframe subset A.

The state selection unit 15 selects a transmission state based on the CQI report acquired by the CQI report acquisition unit.
The transmission state includes a first transmission state and a second transmission state. The selection unit 15 selects one of the first transmission state and the second transmission state. The pico BS 1b performs transmission in the selected transmission state. The transmission state may include other transmission states other than the first transmission state and the second transmission state.

In the first transmission state, transmission is performed using the first subframe subset A configured to include one or a plurality of subframes that do not receive interference from the macro BS 1a.
In the second transmission state, only the second subframe subset B configured to include subframes that may receive interference from the macro BS 1a, or both the first subframe subset A and the second subframe subset B, Transmission is performed using.

When the CQI of the second subframe subset B measured by the terminal apparatus 2 is not good, it can be determined that there is much interference from the macro cell and the terminal apparatus 2 that has measured the CQI is located near the cell edge of the picocell PC. Therefore, the state selection unit 15 selects the first transmission state.
On the other hand, when the CQI (communication quality; channel quality) of the second subframe subset B measured by the terminal apparatus 2 is good, there is little interference from the macro cell, and the terminal apparatus 2 that has measured the CQI is near the center of the picocell PC. If it is located, it can be determined. Therefore, the state selection unit 15 selects the second transmission state.
Note that whether or not the CQI of the second subframe subset B is good can be determined by comparison with a threshold value indicating whether or not the CQI is good.

Further, when the CQI measurement result of the first subframe subset A is also obtained, the CQIs of both subsets A and B may be compared. The state selection unit 15 can select a state in which a subset having a better CQI is used.

In addition, when the difference between the CQIs of both subsets A and B is greater than or equal to a predetermined value, the state selection unit 15 selects a state in which only the subset with the better CQI is used, and when the difference is less than the predetermined value, the CQI It is possible to select a state in which only the subset with the worse is used. This can be determined that the terminal device 2 is at the center of the pico BS 1b when the difference between the CQIs of both subsets A and B is small. The subset used by the terminal device 2 near the cell edge is expected to be crowded with many terminal devices 2 that the user wants to use. Therefore, when the difference is less than the predetermined value, it is possible to avoid congestion by using only the subset with the worse CQI.

Further, the state selection unit 15 may perform state selection so that it is not used for subset transmission in which the CQI is equal to or smaller than a predetermined value, and only the ABS subset whose CQI is equal to or larger than the predetermined value is used. In this case, as long as all the CQIs of a plurality of subsets are equal to or greater than a predetermined value, a plurality of subsets may be used simultaneously.

The terminal device 2 includes a subset information acquisition unit 21, a CQI measurement unit 22, and a CQI report transmission unit 24.
The subset information acquisition unit 21 acquires subset information from the base station device (pico PBS 1b) to which the terminal device 2 is connected.
The CQI measurement unit 22 measures CQIs of subframes constituting the second subframe subset B based on the subset information acquired by the subset information acquisition unit 21. The CQI measurement unit 22 can also measure the CQI of the subframes constituting the first subframe subset A or the CQI of the entire frame.

The CQI report transmission unit 24 transmits a report (CQI report) on the measurement result measured by the CQI measurement unit 22 to the base station apparatus (pico BS 1b). The CQI report includes the measurement result of the second subframe subset B, the measurement result of the first subframe subset A, and / or the measurement result of the entire frame.

[5. Basic concept of transmission state selection processing to avoid interference]
FIG. 8 shows a processing procedure for the pico BS 1b to select an appropriate transmission state for avoiding interference from the macro cell.
First, the ABS information acquisition unit 11 of the pico BS 1b acquires the ABS information of the macro BS (step S1-1). As shown in FIG. 9, the acquisition of ABS information can be performed from the macro BS 1a through the network between base stations. Moreover, pico BS1b may acquire ABS information from macro BS1a by radio | wireless communication, and may acquire ABS information by radio | wireless communication from the terminal device (MUE) 2 connected to macro BS1a.

Subsequently, the pattern selection unit 12 determines two subframe subsets A and B based on the acquired ABS information (pattern selection; step S1-2). The first subframe subset A mainly includes one or a plurality of subframes corresponding to the ABS of the macro cell, and the second subframe subset B mainly includes timings other than the timing corresponding to the ABS of the macro cell. 1 or more subframes are included.

The subset information notification unit 13 transmits subset information indicating the first and second subframe subsets A and B determined by the pattern selection unit 12 to the terminal apparatus (pico UE) 2 in the pico cell PC (step S1- 3).
The subset information acquisition unit 21 of the terminal device (pico UE) 2 acquires the subset information notified from the pico BS 1b (step S1-4).
The CQI measurement unit 22 measures CQI in the subframes constituting the second subframe subset B (step S1-5). The measurement of CQI is performed for each subframe constituting the second subframe subset, and the average value of the measurement results for each subframe becomes the CQI of the second subframe subset.

The CQI report transmission unit 24 wirelessly transmits the CQI measurement result of the second subframe subset B to the pico BS 1b as a CQI report (step S1-6).
The CQI report acquisition unit 14 of the pico BS 1b receives the CQI report transmitted by the terminal device 2 (step S1-7).
Then, the state selection unit 15 selects an appropriate transmission state from the first transmission state and the second transmission state based on the acquired CQI report, and the pico BS 1b transmits to the terminal device 2 that has transmitted the CQI report. On the other hand, transmission is performed in the selected transmission state.

[6. Specific procedure for transmission status selection processing]
[6.1 First Example]
According to the processing procedure shown in FIG. 8, the pico BS 1 b can select an appropriate transmission state after communication for notification of subset information or the like is performed between the pico BS 1 b and the terminal device 2. That is, the pico BS 1b acquires the CQI report (step S1-7), and transmission from the pico BS 1b to the terminal device 2 is performed even before an appropriate transmission state is selected (S1-8).

In this embodiment, in order to optimize transmission before CQI report acquisition, transmission is performed in the first transmission state using the first subframe subset A before CQI report acquisition, as shown in FIG.

As shown in FIG. 10, transmission from the pico BS 1b to the terminal device 2, such as RACH Procedure and RRC connection setup, is performed in the first transmission state using only the first subframe subset A.
The RACH procedure is to determine and notify the user ID (C-RNTI) required for uplink timing synchronization and PHY layer communication. The RRC connection setup notifies whether the communication channel (Radio Bear) between the terminal device and the base station device is available and the channel configuration information.
In the present embodiment, the RRC connection setup includes configuration information (TS36.331 CQI-ReportConfig) related to the CQI report, and the terminal device 2 sends the CQI report to the base station device after acquiring the configuration information. It can be sent.
The RRC connection request is a message related to radio connection control that requests establishment of an RRC layer connection so that communication can be performed between the terminal device and the base station device.

FIG. 10 shows that the CQI measurement by the CQI measurement unit 22 of the terminal device 2 is performed after the connection (RRC Connection) establishment process (wireless connection control) (step S2-1). After acquiring the CQI report from the terminal device 2, the state selection unit 15 of the pico BS 1b selects the first transmission state or the second transmission state (step S2-2). Note that, in S2-2 of FIG. 10, the selection by the selection unit 15 is shown as the determination of whether or not the second subframe subset B can be used (whether or not the second transmission state can be used).

When acquiring the CQI report, the selection unit 15 selects the second transmission state when determining that the second subframe subset B may be used based on the acquired CQI report. That is, the terminal device 2 communicates using only the second subframe subset B, or communicates using the first and second subframe subsets A and B together.
On the other hand, when the state selection unit 15 determines that the second subframe subset B is unusable, the state selection unit 15 selects the first transmission state.

As described above, before the state selection unit 15 makes a selection based on the CQI report, the state selection unit 15 automatically selects the first transmission state until the CQI report is acquired. Therefore, transmission using only the first subframe subset A is performed during the connection establishment process and until the CQI report is acquired after the connection is established.

This is due to the following reason. That is, when the terminal device 2 tries to establish a connection with the base station device, the base station device cannot recognize the position of the terminal device 2 until it obtains the CQI report. While the position of the terminal device 2 cannot be recognized, it is preferable that the terminal device 2 is considered to be located near the cell edge that is more susceptible to interference.
Therefore, until the CQI report is acquired, the state selection unit 15 of the pico BS 1b assumes that the terminal device 2 is located in the vicinity of the cell edge without being based on the CQI report, and the first subframe for the vicinity of the cell edge. A first transmission state using subset A is selected.

Also, as shown in FIG. 10, the subset information notification unit 13 sends the subset information to the terminal device 2 from the pico BS 1b for connection establishment processing between the terminal device 2 and the pico BS 1b (such as RRC Connection Setup). Message in the wireless connection control). Thereby, the subset information acquisition part 21 of the terminal device 2 can acquire subset information with reception of the message during the connection establishment process, and can perform CQI measurement by the terminal device 2 relatively early.

As described above, in this embodiment, for the notification of the subset information from the pico BS 1b to the terminal device 2, the information is exchanged by transmission (Signaling) of the RRC layer of the pico BS 1b and the terminal device 2.

FIG. 11 shows a specific example of IE (Information Element) indicating subset information. In FIG. 11, the subframe subset is represented by the name “ABS Subset”.
The “ABS Subset Information Element” portion of FIG. 11 defines an IE called “absSubset”. In “absSubset”, any one of a plurality of patterns (15 patterns in FIG. 11; patern1 to patarn15) of subframe subset patterns is designated. The pattern here is different from the pattern (subset combination) in FIG. 6 and shows a different pattern of subframes constituting one subframe subset. That is, the subframe which comprises one subframe subset is specified by the pattern of FIG. Note that “absSubset” may designate subframes constituting a subframe subset by a bitmap or the like.

The part of “ABS Subset List Information Element” in FIG. 11 defines the IE “ABSSubsetList-v10x0”. In “ABSSubsetList-v10x0”, a combination of the first subframe subset A and the second subframe subset B is designated. Here, for example, “absSubset” that is the first subframe A is designated by the name “ABSsusetPrimary”, and “absSubset” that is the second subframe subset B is designated by the name “ABSsusetSecondary”.

The subset information can be transmitted by being included in other messages transmitted from the base station apparatus to the terminal apparatus such as RRC Connection Reconfiguration in addition to RRC Connection Setup.
RRC Connection Setup or RRC Connection Reconfiguration, which is a message in wireless connection control, has “radioResourceConfigDedicated” as a common IE. “RadioResourceConfigDedicated” defines setting information related to radio. When the subset information (“ABSSubsetList-v10x0”) is included in RRC Connection Setup or RRC Connection Reconfiguration, for example, as shown in FIG. 12, the subset information (“ABSSubsetList-v10x0”) shown in FIG. 11 is included in “radioResourceConfigDedicated”. Can be stored.
Note that the addition of subset information is optional, and the subset information is not included in the message when it is not necessary to notify the subset information.

As described above, according to the present embodiment, an appropriate transmission state is selected even before the base station apparatus acquires a CQI report. Moreover, information indicating the subframe subset for which CQI is to be measured is notified to the terminal device at an early stage.

[6.2 Second Example]
In FIG. 10, the subset information is transmitted by being included in the RRC connection Setup message transmitted during the connection establishment process, whereas in the second example shown in FIG. 13, the subset information is broadcast information (Broadcast Information). And transmitted in the system information (SIB).

Since the subset information is transmitted as broadcast information, the terminal device 2 can acquire the subset information even before the connection establishment process is performed (when the terminal device is in an idle state).

When starting the connection establishment process, the pico BS 1b transmits in the first transmission state using the first subframe subset A until the CQI report is acquired, similarly to the procedure shown in FIG. That is, RACH Procedure is performed in the first transmission state using only the first subframe subset A.

However, since the terminal device 2 has acquired the subset information before the connection establishment process, the CQI measurement unit 22 can immediately measure the CQI when synchronization is established with the pico BS 1b by the RACH procedure. Yes (step S3-1).
Therefore, the state selection unit 15 of the pico BS 1b can acquire the CQI report from the terminal device 2 and select the first transmission state or the second transmission state at a relatively early stage of the connection establishment process (Step S3). -2).
That is, in the procedure shown in FIG. 13, the transmission state can be selected relatively earlier than the procedure shown in FIG.

[6.3 Third Example]
14 to 16 show an example in which the subset information is notified to the terminal device 2 during the handover process.
When the terminal apparatus 2 starts communication with the macro BS 1a (step S4-1) and is in communication (step S4-2), the terminal apparatus 2 is connected to the area PC of the pico BS 1b as shown in FIG. (Step S4-3), the macro BS 1a determines whether or not the terminal device 2 needs to be handed over from the macro BS 1a to the pico BS 1b (step S4-4).

As a result of determining whether or not a handover is necessary, if it is determined that a handover is necessary, a handover process shown in FIG. 16 is performed.
Prior to the handover process, the pico PS 1b acquires the ABS information of the macro BS 1a (step S4-5). Step S4-5 is the same processing as step S1-1 in FIG. 8, and various methods shown in FIG. 9 can be adopted as the ABS information acquisition method.

As shown in FIG. 16, when the macro BS 1a transmits a handover request (Handover Request) to the pico BS 1b for handover, the pico BS 1b sends a response to the handover request (Handover Request Acknowledge) to the macro BS 1a. return.
In the third example, the notification unit 13 of the pico BS 1b includes the subset information in a response to the handover request (Handover Request Acknowledge) and notifies the macro BS 1a.

The macro BS 1a that has received the subset information notifies the terminal device 2 of RRC Connection Reconfiguration (handover command), which is one of the messages during the handover process. RRC Connection Reconfiguration includes subset information received by the macro BS 1a.

Therefore, the terminal device 2 that has received the RRC Connection Reconfiguration (handover command) can obtain subset information.
Thus, in the third example, subset information is notified from the pico BS 1b to the terminal device 2 via the macro BS 1a. Moreover, during the handover process, the terminal device 2 can communicate not only with the pico BS 1b that is the target base station device but also with the macro BS 1a that is the source base station device, so that the subset information is transmitted from the pico BS 1b to the macro BS 1a. It is suitable for notifying to the terminal device 2 via.

In the third example, as in the second example, the subset information is obtained before the RACH procedure is performed.
And pico BS1b transmits in the 1st transmission state using the 1st sub-frame subset A until it acquires a CQI report. However, as in the second example, since the subset information is acquired in advance, the CQI measurement unit 22 can immediately measure the CQI when synchronization is established with the pico BS 1b by the RACH procedure ( Step S5-1).
Therefore, the state selection unit 15 of the pico BS 1b can acquire the CQI report from the terminal device 2 and select the first transmission state or the second transmission state at a relatively early stage before the completion of the handover process (Step S1). S5-2).

[6.4 Fourth Example]
FIG. 17 shows the configuration of the pico BS 1b and the terminal device 2 in the fourth example. The configuration of the pico BS 1b shown in FIG. 17 is common to the configuration of the pico BS 1 shown in FIG. The terminal device 2 shown in FIG. 17 is obtained by adding a timing control unit 23 to the terminal device 2 shown in FIG.
The timing control unit 23b controls the timing at which the CQI measurement unit 22 executes CQI measurement.

[6.4.1 CQI prior measurement in idle mode]
In the fourth example, as illustrated in FIG. 18, the terminal device 2 of the present embodiment is located in the pico cell PC, but in the idle mode in which the connection with the pico BS 1b is not established, CQI is measured in advance. And the terminal device 2 transmits a CQI report with respect to pico BS1b, when changing to the connection establishment mode (Connected Mode) with pico BS1b from idle mode. Thereby, pico BS1b can select an appropriate transmission state at an early stage.

[6.4.1.1 Prior notification of subset information]
In the present embodiment, for the notification of the subset information from the pico BS 1b to the terminal device 2, information is exchanged by transmission (Signalling) of the RRC layer of the pico BS 1b and the terminal device 2.
As shown in FIG. 19, the subset information notification unit of the pico BS 1 b is used in order to cause the terminal device 2 in an idle state in which the connection (RRC Connection) with the pico BS 1 b is not established to acquire the subset information transmitted from the pico BS 1 b in advance. 13 transmits subset information included in broadcast information (system information; SIB) (step S6-1). Even if the connection with the base station apparatus is not established, the terminal apparatus 2 located in the picocell PC can read the system information that is broadcast information.
Therefore, the subset information acquisition unit 21 of the terminal device 2 can acquire the subset information included in the broadcast information in advance by receiving the broadcast information from the pico BS 1b even if the terminal device 2 is in the idle mode (step S1). S6-2). Further, since the subset information is transmitted as broadcast information, the common subset information can be simultaneously notified to all the terminal devices 2 in the cell PC.

As another method of causing the terminal device 2 to acquire the subset information in advance, there is a method of using the location registration process of the terminal device 2.
The location registration process is a process for registering the area (cell) where the terminal device 2 is located in the management apparatus (MME) of the inter-base station network. In the location registration process, a process of temporarily establishing a connection (RRC Connection) between the terminal apparatus 2 and the base station apparatus 1 and entering a connection establishment mode is performed. When the location registration process ends, the terminal device 2 returns from the connection establishment mode to the idle mode, and the radio link between the terminal device 2 and the base station device 1 is disconnected.

When the subset information is acquired in advance by the terminal device 2 using the location registration process, the terminal device 2 transitions from the idle mode (Idle Mode) to the connection establishment mode (Connected Mode) in order to start the location registration process. At the time of transition (transition of (1) in FIG. 20), while in the connection establishment mode for the position registration process, or when transitioning from the connection establishment mode to the idle mode for the end of the position registration process (FIG. 20). In (2) transition), the subset information may be transmitted from the pico BS 1b to the terminal device 2.
Then, the terminal apparatus 2 has already acquired the subset information in the idle mode before establishing the connection with the pico BS 1b for communication thereafter.

FIG. 21 shows messages exchanged among the terminal device (pico UE) 2, the pico BS 1b, and the MME 3 for the location registration process.
In FIG. 21, the subset information notified to the terminal device 2 is included in a message transmitted from the pico BS 1b to the terminal device 2, for example, a message in wireless connection control such as RRC Connection Setup or RRC Connection Reconfiguration. .

FIG. 22 shows a specific example in which the system information (SIB2) is defined including the subset information (“ABSSubsetList-v10x0”) defined as shown in FIG. In FIG. 22, the underlined portion is the subset information portion in SIB2. The subset information notification unit 13 of the pico BS 1b generates SIB2 as shown in FIG. 22 and transmits it as broadcast information. Thereby, pico BS1b can transmit the subset information which shows the 1st and 2nd sub-frame subsets A and B as alerting | reporting information.
Note that the system information (broadcast information) shown in FIG. 22 can also be used when subset information is included in the system information (broadcast information) and transmitted as in the second example.

Moreover, the subset information acquisition part 21 of the terminal device 2 can acquire subset information by receiving SIB2 and taking out the subset information contained in SIB2.
Note that the broadcast information including the subset information is not limited to SIB2. For example, the subset information acquisition unit 21 may be stored in another SIB other than SIB2. In addition, addition of subset information is an option, and subset information is not included in SIB2 when it is not necessary to notify subset information.

When the subset information (“ABSSubsetList-v10x0”) is included in RRC Connection Setup or RRC Connection Reconfiguration, for example, as shown in FIG. 12, the subset information (“ABSSubsetList” defined in “radioResourceConfigDedicated” as shown in FIG. -v10x0 ”) can be stored.
Note that the addition of subset information is optional, and the subset information is not included in the message when it is not necessary to notify the subset information.

[6.4.1.2 Prior measurement of CQI]
Since the terminal device (mobile terminal) 2 may move even in the idle mode, the pico BS 1b cannot recognize the position (near the cell edge or the cell center) of the terminal device 2 in the idle mode at the pico cell PC.
Therefore, the CQI measuring unit 22 of the terminal device 2 in the idle mode performs CQI measurement based on the subset information obtained from the broadcast information or obtained in the connection establishment processing procedure (wireless connection control) for the location registration process. Go in advance. By performing CQI measurement in the idle mode in advance, the terminal device 2 can promptly transmit a CQI report to the pico BS 1b when establishing a connection with the pico BS 1b or thereafter. As a result, the pico BS 1b can recognize the position of the terminal device 2 at an early stage.

FIG. 23 shows a management / measurement procedure of CQI measurement. FIG. 23A shows a processing procedure when the subset information acquisition unit 21 and the timing control unit 23 of the terminal device 2 are provided as functions of the RRC (Radio Resource Control) layer, and the CQI measurement unit 22 is provided as a function of the PHY layer. Is shown. In FIG. 23A, a scheduling function for CQI measurement processing is provided in the MAC layer, which is an intermediate layer between the RRC layer and the PHY layer.

In the first procedure shown in FIG. 23 (a), the RRC layer subset information acquisition unit 21 acquires subset information from the pico BS 1b. In the RRC layer, the acquired subset information is stored and managed (step S7-1). However, the MAC layer and the PHY layer do not manage subset information.
The timing controller 23 of the RRC layer controls the timing of CQI measurement, and notifies the MAC layer of a CQI measurement instruction when it is time to measure CQI. The CQI measurement instruction includes information indicating a subframe subset for which CQI is to be measured.

The MAC layer schedules measurement processing according to the RRC layer CQI measurement instruction (step S7-2), and notifies the PHY layer of the CQI measurement instruction.
The CQI measurement unit 22 of the PHY layer that has received the CQI measurement instruction performs CQI measurement of the subframe subset to be measured in accordance with the instruction (step S7-3). When the CQI report transmission unit 24 is provided in the RRC layer, the CQI measurement result is notified from the PHY layer to the MAC layer, and is further notified from the MAC layer to the CQI report transmission unit 24 in the RRC layer.

In FIG. 23B, the subset information acquisition unit 21 of the terminal device 2 is provided as a function of the RRC layer, the timing control unit 23 and a function of storing and managing the subset information are provided as functions of the MAC layer, and the CQI measurement unit 22 is provided. The processing procedure when provided as a function of the PHY layer is shown.

In the second procedure illustrated in FIG. 23B, when the subset information acquisition unit 21 of the RRC layer acquires the subset information from the pico BS 1b, the subset information acquisition unit 21 notifies the MAC layer of the acquired subset information as a CQI measurement instruction. Receiving the CQI measurement instruction, the MAC layer stores and manages the subset information (step S8-1).
The MAC layer timing control unit 23 performs scheduling to control the timing of CQI measurement by itself (step S8-2), and when it is time to measure CQI, issues a CQI measurement instruction to the CQI measurement unit 22 of the PHY layer. The CQI measurement unit 22 performs CQI measurement. The CQI measurement unit 22 performs CQI measurement for the subframe subset to be measured (step S8-3).

The CQI measurement can be performed periodically in the idle mode or can be performed with a predetermined event as a trigger.
FIG. 24A shows a first processing procedure when CQI measurement is periodically performed. FIG. 24A shows a case where the timing control unit 23 is provided in the RRC layer, and the timing control unit 23 measures a cycle for performing CQI measurement with a timer (steps S9-1 and S9-). 2) A CQI measurement instruction is notified to the MAC layer every predetermined period. In the MAC layer, the CQI measurement instruction is notified to the PHY layer in accordance with the measurement instruction from the RRC layer (step S9-3). Upon receiving the notification, the PHY layer CQI measurement unit 22 performs CQI measurement (step S9-4).
Note that a timer for measuring timing may be provided in the MAC layer.

FIG. 24B shows a second processing procedure when CQI measurement is performed with a predetermined event as a trigger. Here, an event (RRC イ ベ ン ト Connection establishment event) that triggers the start of a connection (RRC Connection) establishment process for establishing a connection between the terminal device 2 and the pico BS 1b is employed as the predetermined event. When an RRC Connection establishment event occurs (step S10-1), the RRC layer timing control unit 23 notifies the MAC layer of a CQI measurement instruction until the RRC Connection procedure is started. The MAC layer notifies the PHY layer of the CQI measurement instruction in accordance with the measurement instruction from the RRC layer (step S10-2). Then, the PHY layer CQI measurement unit 22 performs CQI measurement of the subframe subset to be measured (step S10-3). Then, the CQI measurement result is reported from the PHY layer to the MAC layer. In the MAC layer, a CQI report is created based on the reported CQI measurement result (step S10-4), and is notified from the MAC layer to the CQI report transmission unit 24 of the RRC layer.

[6.4.2 CQI report transmission]
The CQI report transmission unit 24 that has received the CQI measurement result transmits a CQI report to the pico BS 1b. The CQI report transmission unit 24 includes the CQI report in a message (message related to radio connection control) transmitted from the terminal device 2 to the pico BS 1b in order to establish a connection (RRC Connection) between the terminal device 2 and the pico BS 1b. Send.
As a message (message related to wireless connection control) for establishing a connection (RRC Connection), for example, RRC Connection Request, RRC Connection Setup Complete, or RRC Connection Reconfiguration Complete can be used as shown in FIG. By transmitting a CQI report together with a message for establishing a connection (RRC Connection) (message related to wireless connection control), the pico BS 1b can perform transmission in an appropriate transmission state immediately after the connection is established. .
The CQI report may be stored in another message transmitted from the terminal device 2 to the base station device 1 and transmitted.

FIG. 26 shows a specific example of IE (Information Element) indicating a CQI report. In the 3GPP standard specifications, the CQI report is notified from the MAC layer of the terminal device 2 to the base station device. In TS36.213, CQIVvalue (0 to 15), PMI (0 to 15), and RI (0 to 3) are defined as CQI related information. In the present embodiment, as shown in FIG. 26, the definition of the CQI report in TS36.213 is used.

A specific example of the RRC Connection Request message in which the CQI report defined as shown in FIG. 26 is stored is as shown in FIG. FIG. 28 shows a specific example in which the CQI report defined as shown in FIG. 20 is stored in the RRC Connection Setup Complete message. FIG. 23 shows the CQI report defined as shown in FIG. 26 in the RRC Connection Reconfiguration Complete message. Is a specific example in which is stored. In FIG. 27 to FIG. 29, the underlined portion is the CQI report portion.

Further, the CQI report may be transmitted in the MAC layer as in the 3GPP standard specifications. In this case, as shown by “CQI measurement result notification (1)” in FIG. 30, notification can be made at the timing when notification in the MAC layer becomes possible during connection (RRC Connection) establishment processing.
In addition, as shown in “CQI measurement result notification (2)” in FIG. 30, immediately after the connection (RRC Connection) establishment process, notification can be made at a timing when notification in the MAC layer becomes possible.

According to the above embodiment, since the CQI is measured before the connection is established, the base station apparatus performs an appropriate subset for the terminal apparatus immediately after the terminal apparatus and the base station apparatus can communicate with each other. Can be assigned.

[6.5 Fifth Example]
The prior measurement of CQI as in the fourth example is effective when the terminal device 2 is located in the cell area of the pico BS 1b to be connected before the connection is established. However, when the terminal device 2 moves from another cell (for example, the macro cell MC) to the pico cell PC and tries to establish a connection with the pico BS 1b, it is difficult to measure CQI in the pico cell PC in advance. .

Therefore, in the fifth case, when the terminal device 2 tries to perform connection establishment processing, the processing shown in FIG. 31 is executed as preprocessing.
As the pre-processing, when the terminal device 2 is to perform the connection establishment process, first, it is determined whether or not the terminal device 2 has the CQI measurement result (CQI information) of the subset designated by the pico BS 1b that is to establish the connection. Is determined (step S11-1). In the case of having the CQI measurement result (CQI information) of the pico BS 1b trying to establish a connection, the Pico cell PC is in the service area even during the previous idle mode, and [6.4.1 Idle mode] As described in [CQI Prior Measurement in (Idle Mode)], CQI prior measurement is performed in the picocell PC. Therefore, as described in [6.4.2 CQI report transmission], the terminal device 2 executes the first procedure for transmitting the CQI report during the connection establishment process or immediately after the connection process is established.

On the other hand, when it is determined in step S11-1 that the pico BS 1b attempting to establish a connection does not have the CQI measurement result (CQI information) of the designated subset (the CQI measurement result is determined by another base station). The second procedure is executed, including the case of the device.
In the second procedure, since CQI pre-measurement is not performed, CQI measurement and CQI report transmission are performed after the connection between the terminal device 2 and the base station device 1 is established.

FIG. 32 shows a specific example of the second procedure when the CQI measurement result (CQI information) of the subset designated from the pico BS 1b attempting to establish a connection is not included.
In FIG. 26, similarly to FIG. 10, the CQI measurement by the CQI measurement unit 22 of the terminal device 2 is performed after the connection (RRC Connection) establishment process (wireless connection control) (step S12-1). After acquiring the CQI report from the terminal device 2, the state selection unit 15 of the pico BS 1b selects the first transmission state or the second transmission state (step S12-2). Note that, in S12-2 of FIG. 32, the selection by the selection unit 15 is shown as the determination of whether or not the second subframe subset B can be used (whether or not the second transmission state can be used).

When acquiring the CQI report, the selection unit 15 selects the second transmission state when determining that the second subframe subset B may be used based on the acquired CQI report. That is, the terminal device 2 communicates using only the second subframe subset B, or communicates using the first and second subframe subsets A and B together.
On the other hand, when the state selection unit 15 determines that the second subframe subset B is unusable, the state selection unit 15 selects the first transmission state.
Moreover, the state selection part 15 selects a 1st transmission state until it acquires a CQI report. Therefore, transmission using only the first subframe subset A is performed during the connection establishment process and until the CQI report is acquired after the connection is established.

The reason for adopting the second procedure as described above is as follows. That is, when the terminal device 2 tries to establish a connection with the base station device, the terminal device 2 does not have the CQI measurement result because the terminal device 2 has moved from another cell. It can be regarded as immediately after. If it is immediately after movement between cells, the terminal device 2 can be regarded as existing near the cell edge. Therefore, the terminal device 2 is in a position where it is susceptible to interference from other base station devices (macro BS 1a).
Therefore, until the CQI report is acquired, the state selection unit 15 of the pico BS 1b assumes that the terminal device 2 is located in the vicinity of the cell edge without being based on the CQI report, and the first subframe for the vicinity of the cell edge. A first transmission state using subset A is selected.

Note that when the terminal device 2 tries to establish a connection with the base station device, the terminal device 2 does not have the CQI measurement result immediately after the terminal device 2 is turned on from the power-off state. Or when the terminal device 2 returns from the self mode (a mode in which the power is turned on but no communication). In such a case, although the terminal device 2 may actually be located near the center of the pico cell PC, there is no particular problem even if it is assumed that the terminal device 2 is located near the cell edge.

Also in the fifth example, as shown in FIG. 21, the subset information is a message (RRC) transmitted from the pico BS 1b to the terminal device for connection establishment processing (radio connection control) between the terminal device 2 and the pico BS 1b. Message included in a wireless connection control message such as Connection Setup), the CQI measurement by the terminal device 2 can be performed relatively early.
In the fifth example, the RRC connection setup includes configuration information (TS36.331CQI-ReportConfig) related to the CQI report, and the terminal device 2 sends the CQI report to the base station device after acquiring the configuration information. It can be sent.

The CQI report acquisition unit 14 of the pico BS 1b tries to acquire a CQI report during the connection establishment process or immediately after the connection is established for the terminal device 2 that has performed the CQI prior measurement. However, since the terminal device 2 is set to the second procedure shown in FIG. 31, there may be no CQI report transmission during the connection establishment process or immediately after the connection establishment. In this case, the state selection unit 15 maintains the first transmission state, and the CQI report acquisition unit 14 waits for the CQI report to be transmitted.
In FIG. 32, RACH Procedure is for determining / notifying user ID (C-RNTI) necessary for uplink timing synchronization and PHY layer communication.

The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the meanings described above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

For example, the functions of the pico BS 1b described in the embodiment can be provided in other base station devices (particularly, small base station devices) such as the femto BS 1c.

1: Base station apparatus (1a: Macro base station apparatus, 1b: Pico base station apparatus, 1c: Femto base station apparatus)
2: Terminal device 3: MME
5: Gateway 6: S1 interface 7: X2 interface 11: ABS information acquisition unit 12: Pattern selection unit 13: Subset information notification unit 14: CQI report acquisition unit 15: State selection unit 21: Subset information acquisition unit 22: CQI measurement unit 23: Timing controller 24: CQI report transmitter A: First subframe subset B: Second subframe subset

Claims (47)

1. A base station device that performs wireless communication with a terminal device,
   A report acquisition unit for acquiring a report on the measurement result of the communication quality from the terminal device;
   A selection section for selecting a transmission state;
   With
   The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that do not receive interference from other base station apparatuses, and other At least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from the base station device,
   The report acquisition unit acquires, from the terminal device, a report related to a measurement result of communication quality of one or more radio resource subsets including the second radio resource subset,
   When the report is acquired, the selection unit selects one of the first transmission state and the second transmission state as a transmission state to the terminal device based on the report,
   Until the report is acquired, the first transmission state is selected as a transmission state to the terminal device.
2. A notification unit for notifying subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset;
   The base station apparatus according to claim 1, wherein the notification unit notifies the subset information to another base station apparatus that can notify the subset information to the terminal apparatus.
3. A notification unit for notifying subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset;
   The base station apparatus according to claim 1 or 2, wherein the notification unit notifies the subset information to a source base station apparatus in a handover process during a handover process for the terminal apparatus to perform a handover to the own base station apparatus.
4. The base station apparatus according to claim 3, wherein the notification unit notifies the source base station apparatus of the subset information by including the subset information in a message transmitted to the source base station apparatus for handover processing.
5. The base station apparatus according to claim 4, wherein the message transmitted to the source base station apparatus for a handover process is a response to a handover request transmitted from the source base station apparatus.
6. The base station apparatus according to claim 1, further comprising: a notification unit that notifies the terminal apparatus of subset information indicating one or more radio resource subsets including the second radio resource subset.
7. The base station apparatus according to claim 6, wherein the notification unit transmits the subset information as broadcast information.
8. The base station apparatus according to claim 6, wherein the notification unit notifies the terminal apparatus of the subset information during a connection establishment process for establishing a connection between the terminal apparatus and the base station apparatus.
9. The notifying unit includes the subset information in a message transmitted from the base station apparatus to the terminal apparatus for establishing a connection between the terminal apparatus and the base station apparatus, whereby the subset information is included in the terminal apparatus. The base station apparatus according to claim 8.
10. The base station apparatus according to any one of claims 1 to 9, wherein in the second transmission state, transmission is performed using the first radio resource subset and the second radio resource subset.
11. The base station apparatus according to any one of claims 1 to 10, wherein the radio resource is a time resource or a frequency resource.
12. The base station apparatus according to any one of claims 1 to 11, wherein the radio resource is a subframe or a carrier.
13. A terminal device that performs wireless communication with a base station device,
    A measurement unit that measures the communication quality of a radio resource subset including one or more radio resources that may be interfered with by another base station device;
    A transmission unit for transmitting a report on a measurement result by the measurement unit to the base station device;
    A terminal device, comprising: a subset information acquisition unit that acquires subset information indicating a radio resource subset whose communication quality is to be measured by the measurement unit.
14. The terminal apparatus according to claim 13, wherein the acquisition unit acquires the subset information from the other base station apparatus.
15. The terminal device according to claim 13 or 14, wherein the acquisition unit acquires the subset information from a source base station device in a handover process.
16. The subset information is included in broadcast information transmitted from the base station device,
    The terminal apparatus according to claim 13, wherein the subset information acquisition unit acquires the subset information by receiving the broadcast information from the base station apparatus.
17. The measurement unit measures communication quality of a radio resource subset indicated by the subset information included in the broadcast information received before connection establishment processing for establishing a connection between the terminal device and the base station device;
    The terminal device according to claim 16, wherein the transmission unit transmits the report during the connection establishment process.
18. The subset information is included in a message transmitted from the base station apparatus to the terminal apparatus for establishing a connection between the terminal apparatus and the base station apparatus,
    The terminal apparatus according to claim 13, wherein the subset information acquisition unit acquires the subset information by receiving the message from the base station apparatus.
19. A wireless communication system including a base station device and a terminal device that performs wireless communication between the base station device,
    The base station device includes a report acquisition unit that acquires a report on a measurement result of communication quality from the terminal device, and a selection unit that selects a transmission state,
    The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that do not receive interference from other base station apparatuses, and other At least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from the base station device,
    The report acquisition unit acquires, from the terminal device, a report related to a measurement result of communication quality of one or more radio resource subsets including the second radio resource subset,
    When the report is acquired, the selection unit selects one of the first transmission state and the second transmission state as a transmission state to the terminal device based on the report,
    Until the report is acquired, the first transmission state is selected as a transmission state to the terminal device.
20. The base station apparatus further includes a notification unit that notifies subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset,
    The notification unit notifies the subset information to another base station apparatus that can notify the subset information to the terminal device,
    The radio communication system according to claim 19, wherein the another base station apparatus notifies the subset information to the terminal apparatus.
21. A method in which a base station apparatus selects a transmission state,
    The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that do not receive interference from other base station apparatuses, and other At least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from the base station device,
    The base station device
    The first transmission state is selected as the transmission state to the terminal device until a report on the communication quality measurement result of one or more radio resource subsets including the second radio resource subset is obtained from the terminal device. And
    When the report is acquired, one of the first transmission state and the second transmission state is selected as a transmission state to the terminal device based on the report.
22. A method for transmitting information from a base station device to a terminal device,
    The information is subset information indicating a radio resource subset configured to include one or a plurality of radio resources to be measured for communication quality by the terminal device,
    The base station apparatus notifies the subset information to another base station apparatus that can notify the subset information to the terminal apparatus,
    The other base station apparatus transmits the subset information to the terminal apparatus.
23. A base station device that performs wireless communication with a terminal device,
    A report acquisition unit for acquiring a report on the measurement result of the communication quality from the terminal device;
    A selection section for selecting a transmission state;
    With
    The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that do not receive interference from other base station apparatuses, and other At least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from the base station device,
    The report acquisition unit acquires, from the terminal device, a report related to a measurement result of communication quality of one or more radio resource subsets including the second radio resource subset,
    The selection unit selects one of the first transmission state and the second transmission state as a transmission state to the terminal device based on the report transmitted from the terminal device,
    The report acquired by the report acquisition unit indicates the communication quality of one or a plurality of the radio resource subsets including the second radio resource subset before the connection between the terminal apparatus and the base station apparatus is established. A base station apparatus characterized by being related to a measurement result obtained by causing the apparatus to perform measurement.
24. The base station apparatus according to claim 23, further comprising a notification unit that notifies the terminal apparatus of subset information indicating one or a plurality of the radio resource subsets including the second radio resource subset.
25. The base station apparatus according to claim 24, wherein the notification unit transmits the subset information as broadcast information.
26. The base station apparatus according to claim 24, wherein the notification unit notifies the subset information to the terminal apparatus during a position registration process for registering an area where the terminal apparatus is located.
27. 27. The report acquisition unit acquires the report from the terminal device during a connection establishment process for establishing a connection between the terminal device and the base station apparatus or immediately after the connection establishment process. The base station apparatus according to item 1.
28. The report is included in a message transmitted from the terminal device to the base station device for establishing a connection between the terminal device and the base station device,
    The base station apparatus according to claim 27, wherein the report acquisition unit acquires the report by receiving the message from the terminal apparatus.
29. The report acquisition unit, during the connection establishment process or immediately after the connection establishment process, a message transmitted from the terminal apparatus to the base station apparatus for establishing a connection between the terminal apparatus and the base station apparatus; The base station apparatus according to claim 27, wherein the report is acquired from the terminal apparatus.
30. 30. The selection unit performs selection based on communication quality of the second radio resource subset or based on communication quality of the first radio resource subset and the second radio resource subset. The base station apparatus according to item 1.
31. The base station apparatus according to any one of claims 23 to 30, wherein the selection unit selects the first transmission state as a transmission state to the terminal apparatus until the report is acquired.
32. A terminal device that performs wireless communication with a base station device,
    A measurement unit that measures the communication quality of a radio resource subset including one or more radio resources that may receive interference from other base station devices;
    A transmission unit for transmitting a report on a measurement result by the measurement unit to the base station device;
    With
    The terminal device characterized in that the measurement unit measures the communication quality of the radio resource subset before the connection between the terminal device and the base station device is established.
33. A function of acquiring the radio resource subset from the base station device is provided as a function of the RRC layer,
    The measurement unit is provided as a function of the PHY layer,
    The measurement unit of the PHY layer measures the communication quality of the radio resource subset based on timing controlled by the RRC layer or a layer between the RRC layer and the PHY layer. Terminal device.
34. The terminal device according to claim 32 or 33, further comprising a control unit that controls timing at which the measurement unit measures the communication quality of the radio resource subset.
35. The terminal device according to claim 34, wherein the control unit periodically gives an instruction to measure the communication quality of the radio resource subset to the measurement unit.
36. When the event that triggers the start of connection establishment processing for establishing a connection between the terminal device and the base station device occurs, the control unit instructs the measurement unit to measure the communication quality of the radio resource subset The terminal device according to claim 34.
37. The terminal apparatus according to any one of claims 32 to 36, further comprising a subset information acquisition unit that acquires subset information indicating the radio resource subset from the base station apparatus.
38. The terminal apparatus according to claim 37, wherein the subset information acquisition unit acquires the subset information transmitted from the base station apparatus as broadcast information from the base station apparatus.
39. The terminal device according to claim 37, wherein the subset information acquisition unit acquires the subset information from the base station device during a location registration process for registering an area where the terminal device is located.
40. The transmission unit transmits the report to the base station apparatus during a connection establishment process for establishing a connection between the terminal apparatus and the base station apparatus or immediately after the connection establishment process. The terminal device according to item 1.
41. The transmission unit includes the report in a message transmitted from the terminal device to the base station device to establish a connection between the terminal device and the base station device, thereby causing the base station device to include the report. 41. The terminal device according to claim 40.
42. The transmission unit is a message transmitted from the terminal device to the base station device to establish a connection between the terminal device and the base station device during the connection establishment process or immediately after the connection establishment process. The terminal device according to claim 16, wherein the report is transmitted separately to the base station device.
43. A wireless communication system including a base station device and a terminal device that performs wireless communication between the base station device,
    The base station device
    A report acquisition unit for acquiring a report on the measurement result of the communication quality from the terminal device;
    A selection section for selecting a transmission state;
    With
    The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that do not receive interference from other base station apparatuses, and other At least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from the base station device,
    The report acquisition unit acquires, from the terminal device, a report related to a measurement result of communication quality of one or more radio resource subsets including the second radio resource subset,
    The selection unit selects either the first transmission state or the second transmission state as a transmission state to the terminal device based on the report transmitted from the terminal device,
    The terminal device
    A measurement unit for measuring communication quality of one or a plurality of the radio resource subsets including the second radio resource subset;
    A transmission unit for transmitting a report on a measurement result by the measurement unit to the base station device;
    With
    The measurement unit performs the measurement of the communication quality before the connection between the terminal apparatus and the base station apparatus is established.
44. A measurement step in which the terminal device measures downlink communication quality;
    A transmission step in which the terminal apparatus transmits a report on the measurement result of the communication quality to a base station apparatus;
    A selection step in which the base station apparatus selects a transmission state;
    Including
    The transmission state includes a first transmission state in which transmission is performed using a first radio resource subset configured to include one or a plurality of radio resources that do not receive interference from other base station apparatuses, and other At least a second transmission state in which transmission is performed using at least a second radio resource subset configured to include one or a plurality of radio resources that may receive interference from the base station apparatus;
    In the measuring step, communication quality of one or more radio resource subsets including the second radio resource subset is measured,
    In the selection step, one of the first transmission state and the second transmission state is selected as a transmission state to the terminal device based on the report transmitted from the terminal device,
    The measurement step is performed before the connection between the terminal device and the base station device is established.
45. A transmission method from a base station apparatus to a terminal apparatus,
    The base station apparatus transmits broadcast information including subset information indicating a radio resource subset configured to include one or a plurality of radio resources whose communication quality should be measured by a terminal apparatus.
46. A transmission method from a base station apparatus to a terminal apparatus,
    The base station apparatus transmits a subset information indicating a radio resource subset including one or a plurality of radio resources whose communication quality is to be measured by a terminal apparatus in a message in radio connection control. how to.
47. A transmission method from a terminal device to a base station device,
    A method of transmitting a report of communication quality measurement results included in a message in wireless connection control.

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